Computing and like machine



p 12, 1939. G. G. GOING 2,172,149

COMPUTING AND LIKE MACHINE Filed Aug. 23, 1934 ll Sheets-Sheet 1 WITNESSES I uvvs/vrm? 5 Q GEORGE 6. GOING ffi/ BY ATTORNEY Sept. 12, 1939. G. G. GOING COMPUTING AND LIKE MACHINE ll Sheets-Sheet 2 Filed Aug. 23, 1934 INVENTOR GEORGE G. GOING ATTORNEY Sept. 12, 1939. G. G. some COMPUTING AND LIKE MACHINE Filed Au 23 1 INVENTOR GEO/F65 6. 60/N6 WM ATTORNEY 5 ll Sheets-Sheet 3 Sept. 12, 1939. e. G. some I COMPUTING AND LIKE MACHINE Filed Aug. 23, 1934 11 Sheets-Sheet 4 I I m6 uvvzzvron GEORGE 6 some ATTORNEY p 2, 1939. a e. G. some 2,172,749

COMPUTING AND LIKE MACHINE Filed Aug. 23, 1934 ll Sheets-Sheet 5 IN VEN TOR G50R6E G. GOING A TTORNEY Sept. 12, 1939. G. G. some 2,172,749

COMPUTING AND LIKE MACHINE Filed Aug. 25, 1954 ll'Sheets-Sheet 6 INVENTOI? GEORGE G GOING ATTORNEY Sept. 12, 1939. ca. 6. some COMPUTING AND LIKE MACHINE Filed Aug. 25, 1954 11 Shets-Shpet 7 IN VENTOR GEORGE q. GOING BY%/ A TTORNEV Sept. 12, 1939.

G. G. GOING COMPUTING AND LIKE MACHINE Filed Aug. 23, 1934 ll Sheets-Sheet 8 .0 nww n whw \l l\ a 2km k m m o S 5 m3 IN VEN TOR GEORGE 6. GOING A T TOR/YE Y 11 Sheets-Sheet 9 G. G. GOING COMPUTING AND LIKE MACHINE Filed Aug. 23, 1934 Sept. 12, 1939.

@352 g QQQQQQQQQQ M a m9 3 m a 4% n a a ma mi W: a W m s wQ w m Ill n Y B -H H. mm mm mm M u u a 1 I P MH Sm m5 mmmu A m B a 8m wamfin 5 35w n m U m m In) i lq .3 III) m. H w 3: 2 I n H N I H m n Q w 5 Na m3 x0.

Sept. 12, 1939. G. a. some COMPUTING AND LIKE MACHINE Filed Aug. 23, 1934 ll Sheets-Sheet 1O INVENTOR I GEORGL' G. GO/IYG WITNESSES I A TTOIPNEV Sept. 12, 1939. G G, GOING COMPUTING AND LIKE MACHINE Filed Aug. 23, 1934 ll Sheets-Sheet 11 ANN INVENTOR 650/?65 6. GOING ATTdR/VEY Patented Sept. 12, 1939 PATENT OFFICE CODIPUTING AND LIKE MACHINE George G. Going, Utica, N. Y., assignor to Remington Rand Inc., Buffalo, N. Y., a corporation oi. Delaware Application August 23,

15 Claims.

This invention relates to combined typewriting and computing machines and more particularly to an automatic total printing mechanism for such machines.

One of the primary objects of the present invention is to provide means for automatically printing a total in accordance with and as determined by the total set up in the totalizer, said total being printed digit by digit and at a common printing point.

Another object of my invention is to provide mechanism for the automatic-and correct printing of totals, both positive and negative.

A further object is to provide algebraic calculating mechanism including means for inserting the fugitive 1" into the totalizer when said totalizer registers in a negative amount.

Still another object is to provide a combination of electric and mechanical means for effecting the automatic printing of a total, either positive or negative.

My invention further aims to provide in a combined typewriting and computing machine, an electro-mechanical automatic total printing mechanism, including an algebraic totalizer, actuating gear shift mechanism and a plurality of electric circuits, and means for shifting said actuating gears, changing the electric circuits and inserting a fugitive 1 into said totalizer when a negative total is to be printed.

A further object of my invention is to provide means 'of the character specified above which may be readily incorporated in existing machines, such for example as the Remington electrified bookkeeping machine, withgut changing or materially changing the existing structural features thereof.

To the above and other ends which will hereinafter appear, my invention consists in the features of construction, arrangements of parts and combinations of devices set forth in the fore and aft sectional view of the upper front following description and particularly pointed out in the appended claims.

In the drawings wherein like reference characters designate corresponding partsin the different views:

Fig. 1 is a fragmentary, side elevational view of the front portion of a combined typewriting and computing machine in which my invention is embodied;

Fig. 2 is an enlarged, fragmentary, vertical portion of the machine taken substantially along the line 2-2 of Fig. 3 and looking in the direction of the arrows at said line;

1934, Serial No. 741,115

Fig. 3 is an enlarged, fragmentary, front elevational view partly in section of the upper righthand portion of the machine;

Fig. 4 is an enlarged, vertical force and aft sectional view of the cross totalizer taken substan- 5 tially on the line 4-| of Fig. 3 and looking in the direction of the arrows at said line;

Fig. 5 is an enlarged, detail, fragmentary, horizontal sectional view taken along the line 55 of Fig- 4 and looking in the direction of the arrows at said line, the view showing the righthand side plate of the cross totalizer;

Fig. 6 is an enlarged, detail, fragmentary, horizontal sectional view taken along the line 6--6 of Fig. 1 and locking in the direction of the arrows at said line, the view showing the lock for the total key;

Fig. '7 is an enlarged, detail, perspective view of one of the contact selector gears of the cross totalizer, the parts of said gear being shown detached and separated;

Fig. 8 is an enlarged, detail, perspective view of the space key trip-finger and its associated parts, the view showing the parts detached and separated; v

Figs. 9 and 10 are enlarged, detail, perspective views of the fugitive 1 carrying wheel and the actuating arm therefor;

Fig. 11 is a fragmentary, front elevational view showing the connections of the credit balance key to the credit-balance switch and the fugitive l mechanism;

Fig. 12 is a front elevational view, partly in section, of some of the actuating devices and change gear mechanism of the computing mech- 35 anism;

Fig. 13 is a horizontal cross sectional view along the line I 3-43 of Fig. 1 and looking in the direction of the arrows at said line, the view showing some of the details of the credit balance switch; 40

Fig. 14 is a top plan view of the credit balance switch showing the cross wiring connections;

Fig. 15 is a vertical sectional view taken along the line i5i5 of Fig. 14 and looking in the direction of the arrows at said line;

Fig'. 16 is a wiring diagram showing the necessary electric circuits used in the machine constructed in accordance with my invention, particularly the circuits between the totalizer contacts, the credit balance switch and the key actuating solenoids;

Figs. 17, 18 and 19 are diagrammatic plan views of one of the contact levers and a trip pawl, show- I ing the three positions these parts assume to closethe associated contact during a letter Fig. 20 is a fragmentary vertical fore and aft sectional view of the lower portion of the machine showing the power actuating mechanism for the computing and printing mechanisms.

Fig. 21 is a plan view of a modified form of credit balance switch;.

Fig. 22 is a side elevational view of the switch shown in 21;

Fig. 28 is an enlarged vertical cross sectional view taken on the line til-23 of Fig. 21 and looking in the direction or the arrows at said line;

and

Fig. Z lis an enlarged side elevational view of the switch shown in Figs. 21 to 23.

i have shown my invention in the present in stance embodied in a Remington electrified bookkeeping machine similar to that shown and described in the co-pending application of A. Hart Serial No. 511L941, riled; Jan. 1931, now Patent No. 2,963,737, dated December 8, 1936, in which the invention may be readily included without materially modifying the existing structural features of such machine. It should be understood however, that the invention is not restricted to its use in said machine but may be included in combined typewriting and computing machines of the same general type, wherever found available.

As is well LlflOWil, the Remington electrified bookkeeping machine comprises a power actuated Remington typewriter in which is included computing mechanism of the type shown in the patent to J. O. Wahl No. 12705471. In the present instance I have shown only so much of the Reinington electrified bookkeeping machine as is necessary for a complete understandin of my invention as embodied therein, and for any further details of the typewriter, power actuator, or com puting mechanism reference may be made to the above mentioned application and patent.

Before giving a detailed description of the novel mechanism employed to carry out my invention, 1 will first give a brief outline of the theory on which the computing mechanism operates, with a view oi rendering more clear the operation. and purposes of the various portions of the 113.6611 anism as used in conjunction with the devices of my invention.

As before noted, my invention is shown in the present instance embodied in a Remington electrified bookkeeping machine. In this machine, there is provided a typewriter, the digit keys of which are connected to suitable actuating mechanism to the end that two or more wheels, known as the master wheels, will revolve differential amounts depending on the digit key which is actuated. The motion of the master wheels, clue to the operation of the various digit keys, is entered into a vertical and a cross totalizer, each having a step-by-step movement to the left with the typewriter carriage, as will hereinafter appear. Each totalizer contains a group of register wheels and these wheels are connected to the well known l/"Jahl carrying mechanism, to the end that a complete cycle of motion of any register wheel is effective to advance one step the regi wheel of next higher order. The cooperation of this mechanism with the devices of the present invention will hereinafter be more fully pointed out.

The Wahl mechanism. is provided with va .oue

gear shifting or so-called change gear rnearn or reversing the direction of rotation the master erratic wheels, which rotation is brought about by power actuated means upon the operation of any of the digit keys. This vgear shifting may be controlled manually or it may be automatically controlled for the cross totalized by means of cams provided on the vertical totalizers, all as is well known. When the gear shift is in one position, operation of any of the digit keys will result in rotation of the controlled master wheel, or wheels inone direction. When the gear shift is in a second position, operation of any of the digit keys will result in rotation of the controlled master wheel or wheels in the opposite direction. When the gear shift is in the middle, intermediate, or neutral position, operation of any of the numeral keys will not affect the master wheels. These three positions of the gear shifting means will hereinafter be referred to as the adding posh tion, the subtracting position, and the disconnect position. A typical instance of one form of setup of the Remington bookkeeping machine includes one cross totalizer to be used with either a group of, say, four vertical totalizers, or a group or" three vertical totalizers and a dummy totalizer. With this arrangement the machine can be readily adapted for department store bill and. charge work in which a ledger sheet. and superposed bill sheet are printed simultaneously. The entries may be made on the bill and ledger sheet in four columns of figures, the first being for the previous balance, the second for charges, the third for credits and the last for the new balance. The amounts entered into the first two columns are to be added, so the first two vertical totalizers are provided with adding cams to produce an adding in the cross totalizer. The third or credit column contains amounts that are to be subtracted in the cross totalizer so the vertical totalizer'for this column is provided with a subtracting carn to control the gear shift to produce this operation. In order that the crosstotalizer may be set back to zero during the printing of the total to prepare it for a new line of entries, the vertical totalizer employed in connection with the new balance column is provided with a subtracting cam. Thus, as the balance is printed, the amount which shows in the cross totalizer is subtracted out to set it back to zero. it is to be understood that this arrangement of the totalizers is only one of the many set-ups that the Remington bookkeeping machine is adapted for, and though this typical arrangement is to be used during the course of the following description, it is given as a mere illustration.

When writing bills and simultaneously making manifold entries upon a ledger sheet of this sort, the usual procedure is to enter the amounts into the computing mechanism one after another as they are written in their respective columns. The numbers are consequently added or subtracted, as the case may be, into the cross totalizer, so that when the balance column is reached the total or" the amounts previously entered, less the amount subtracted if there be any will appear behind a sight opening or window in the cross totalizer provided for that purpose. When now it is desired to print the total shown in the cross totalizer, the devices of the present invention are called into play. The carriage, which is provided with the usual decimal tabulator mechanism, is tabiuated' to th decimal position of thecligit of highest order in the total. When it comes to rest at point total key is depressed which causes the amount shown in the cross totalizer to be printed automatically into the balance column of the ledger sheet digit by digit, all as will hereinafter more clearly appear.-

Referring now to the drawings, I shall first describe some of the existing structural features of, the Remington electrified bookkeeping machine, and will afterwards describe the devices of the present invention in their combination therewith.

\ From Figs. land 20 it will be seen that the machine comprises a base frame section 28 carrying most of the power driving mechanism and an upper frame section 2| housing the typewriting and calculating mechanism, said upper section 2| being detachably mounted or hinged upon the base section 28 by any suitable means. The power driving devices comprise two main power driven shafts, one a shaft 22 for operating the character or alphabet printing type bars, and the other, a shaft 22 carrying cams 23 for controlling the actuation of the computing mechanism and for actuating the numeral printing type bars. These two shafts receive a continuous rotary motion from an electric motor (not shown) mounted at the rear of the machine upon suitable brackets attached to the base frame section 28. Housed in the upper frame section 2| are the usual typewriting mechanisms comprising character printing keys 24, numeral keys 25, space bar 26, the computing mechanism, and some of their associated operating devices as fully described in the copending application of Hart above referred to and as will be hereinafter'more fully described.

The usual typewriter carriage 21 which is sup ported by roller bearings on the upper frame section 2| and is under -the control of the usual escapement mechanism, carries a truck 28, (Fig. 2) said truck being loosely secured to the carriage 21 by supporting brackets 29 (Fi 11) and guided centrally of the machine by the usual rollers 38 on the actuator frame 30". Mounted on the truck 28 by the usual dovetail construction is a group of vertical totalizers 3|, 3|, 3| and 3| each of which is provided with carrier gears or wheels 32 and gear carrying arms 33. The vertical actuator cooperates with these totalizers, a master wheel 34 giving differential movement to the wheels 32 while a master dog 35 when actuated engages and move one of the gear carrying arms 33.

Somewhat below and to the right of the vertical actuator and likewise secured to the typewriting frame member is the cross actuator which comprises, among its operating parts, a master wheel 36 and a master dog 31 corresponding to the master wheel 34 and master dog 35 in the vertical actuator. The master wheel 36 and master dog 31 are actuated in the usual manner through the usual train of connections (not shown) between the master wheel 34 and the master dog of the vertical totalizer, so that the two master 'wheels and the two master dogs operate in unison. This construction is essentially the same as that disclosed in the above mentioned Patent to Wahl 1,270,471 and an illustration thereof is not deemed necessary. The master wheel 36 and master dog 31 cooperate with the mechanism of a cross totalizer 38 which is removably secured to a cross truck 40 by the usual latch 4|. Rollers 42 mounted on the cross truck 48 engage fixed rails 43 extending between left and right frame plates 44 and 45 (Figs. 3 and 11) to support said truck for reciprocatory movement within its zone of travel, though it is constantly urged toward its normal position at the right by a spring 48.

In order that the cross truck 43 may be given a plurality of reciprocations during a single travel of the vertical totalizer truck 23 in one direction, the number of reciprocations depending on the number of vertical totalizers or dummies used,

a so-called pick-up beam is provided on the cross 5 truck which is successively engaged by lugs on the vertical totalizers. Thus, reference to Fig. 11 will disclose that on the right side of each vertical totalizer is an engaging or pick-up lug 41 which is adapted to engage a hook 48 on a pick-up beam 50. A bracket 5| fastened to the cross truck 48 serves to connect said cross truck to the pick-up beam through a pin and slot connection 52, that also affords a pivotal movement of the beam. Said pick-up beam together with a pick-up guard-53 is given a clockwise urge by a spring 54 secured at one end to the bracket 5| and at the other to a pin in the pick-up beam which passes through an opening in the pick-up guard.

As the 'vertical truck is moved to the left by the typewriter carriage the first vertical totalizer 3| to the left will approach the computing zone and the pick-up lug 41 on said vertical totalizer will engage the hook 43 of the pick-up beam 50. Further movement of the vertical totalizer to the left, after this engagement will cause the pick-up guard 53 which is held in inoperative position by a hook 55 engaging a fixed pin 53, to be released and sprung up to lock the pick-upbeam to the vertical totalizer. Thus, as the carriage continues to move to the left carrying the vertical totalizer 3| over its master wheel 34 the cross truck 48 will be given a corresponding movement to carry the cross totalizer 38 over its master wheel 35. This combined movement continues until the vertical totalizer 3| is about to pass out of the computing zone when a pin 51 carried by the pick-up beam 58 engages a fixed cam 58 to force the hook 48 and pick-up guard 53 in a downward direction, thereby releasing the cross truck 48 which springs to its normal position under the tension of its returning spring 46. Having returned tonormal position the hook 55 is again engaged by the pin 56 to hold the pick-up guard in inoperative position, leaving the cross truck 4|! in readiness 5 to be picked up by engaging the lug on the next vertical totalizer 3|. I

Reverting again to the set-up for department store bill and charge accounts which was referred to above, it was assumed that the vertical truck was to carry either four vertical totalizers, 3|, 3|, 3| and 3| or three and a dummy. If the dummy totalizer is used in place of the totalizer 3| its only functions will be to pick up the cross truck to carry the cross totalizer 38 through the computing zone to receive the amounts entered in the total or "balance column and to set the cross actuator to subtract so'that as the total is printed it will clear the cross totalizer. If, however, a regular vertical totalizer is used, aside from performing the functions mentioned above for the dummy totalizer, it may be set to add the cross totals and hence will act as an accumulative or grand totalizers.

As the vertical totalizer 3| enters the computing zone for-entering the previous balance" said vertical totalizer, which is provided with an add cam, picks up the cross truck so that the amount entered digit-by-digit will be added into both totalizers; that is to sayin the vertical totalizer 3| and in the cross totalizer 33. After the digit of lowest order has been inserted and the carriage makes its next step to the left, the cross truck is released and it springs back to normal position and is ready to be picked up by the next vertical totalizer M for the entry of the charge. The above described operation is repeated as the said next vertical totalizer El traverses the computing zone for entry of the amount written in the corresponding column on the bill and ledger sheet, this second amount being added into both totalizers. At this point the cross totalizer contains the sum of the amounts entered into the previous balance and the charge columns. The vertical totalizer til employed when making an entry in the third or credit column, is provided with a subtract cam, so that the amount of credit added into the vertical totalizer 3t for this column will be subtracted from the sum of the previous balance and the charge which is already contain 'i in the cross-totalizer. After the vertical totalizer Sl is carried through the computing zone when making an entry in this third column and subtracting the credit the cross totalizer again springs back to normal position and is ready to be picked up by the last vertical totalizer St for registering the new balance, which is the total now present in the cross-totalizer as a result of having passed through the computing zone in making entries in the first three columns.

The mechanism thus far described is all old as is evidenced by the application of Hart, Serial No. 510,941, filed Jan. 24, 1931 and the Wahl Patent No. 1,270,471 above referred to and to which reference may be made for a description of any mechanism these drawings do not show and which Remington bookkeeping machines include, or any mechanism which is particularly referred to and not fully illustrated herein.

1 shall now describe the mechanism which is peculiar to my herein described invention, but owing to its rather complex nature Ishall first explain each section separately, and subsequently describe the cooperation of the various portions of the machine.

The cross totalizer The cross totalizer 3% is similar in its construction to the algebraic totalizer shown and described in the patent to L. S. McCorn, No. 1,753,- 711. There are, however, certain modifications that have been made to adapt the mechanism to the uses of the present invention.

Referring to Figs. 1 and 5, it will be seen that the totalizer 33 comprises a right-hand side plate till, a left-hand side plate till, and various connecting bars or rods 52 secured at their ends by various means to these frame plates and extending transversely between them.

The register wheels are those of an ordinary Remington or W'ahl totalizer and they comprise in each denomination a carrier gear 63 mounted on a transverse shaft 6 3, an intermediate or idler gear t5 carried by a shaft 6 and a pinion (5i mounted on a third transverse shaft 68, said pinion being rigid with a register wheel or dial ill on which the amounts are read.

The transfer mechanism is of the intermittent gear type'and includes the so-called Geneva or stop works gears ll arranged in two different rows and each mounted on a lever :72. The levers '52 are of two different kinds pivoted on frame rods 33 and iii respectively, but all at their upper forward ends rest against stop screws and cooperate with a universal bar 175. In all of the respects mentioned and in all other respects except as hereinafter pointed out, the totalizer shown in the drawings contains all the devices usually in. Wahl totalizers, and is operarvame ated in the well known manner one denomination at a time by the cross actuator master wheel 36 engaging successively the carrying wheels 63 and the master dog 37 engaging successively the transfer levers 72.

On the shaft 66 of the idler gears there is pivoted a lever 'l'l (Fig. 10) which extends through a slot in the casing and is provided at its outward end with a bifurcated. arm l8, the purpose of which will hereinafter be more fully explained. At its inner end the lever 'l'l is provided with a series of gear teeth till which mesh with a series of teeth ti on an operating wheel or disk 82, shown in Fig. 9 in perspective as viewed from the left. The disk or wheel 82 is pivoted on the shaft lid of the carrier gears 63 just to the right of the carrier wheel of lowest order.

The wheel 82 has for its purpose to carry to the wheel iii of lowest order, the so-called fugitive l, which must be subtracted or added every time an algebraic totalizer changes from a positive to a negative total, or vice versa. The construction of this wheel is very similar to that of the carrying wheels 63, for like said wheels 63 it is made in the present instance in three planes or stratum. The right-hand strata of a carrying wheel Gil includes the usual thirty teeth, whereas in the wheel 82 there are the teeth 8i meshing with those provided on the lever ll. In the middle plane there are three transfer teeth 33 on .each carrying wheel but on the wheel 82 there is only one. The left-hand plane of both wheels consists of a locking disk having a circular perimeter 8 3, but broken by notches 85 one for each transfer tooth 83 of each of said wheels. It will be noticed that the transfer tooth 83 of wheel 82 is integral with a flange St in the plane of the teeth iii. A lever 12 and transfer gear ll are provided to connect this wheel with the carrying wheel 63 of lowest denominational order in exactly the same way said wheel 63 would be connected with the next one by transfer mechanism, as is well known in totalizers of this kind. It will be perceived that whenever the handle W is moved upward from the position shown in Fig. 4, the tooth Elli of wheel 82 is moved from one side to the other of an adjacent tooth on the usual star wheel 81 of the transfer or Geneva gear ll, with the result that the wheel 63, and in fact the whole gear train of lowest order will be moved one tooth in subtracting direction. When said handle is then moved downward the wheels turn in an adding direction back to normal position.

In order to limit the extent of the rocking motion of the wheel 82 in both directions, a pin or stud 88 is riveted in the side plate fill and projects into the plane of the wheel 82. The righthand stratum of said wheel is cut away so as to leave two lugs Qil and 9i in such position that I one of them engages the stud 88 to arrest the the rod 13 and drawn downward by a spring 95,

similar to those which control the levers 12.

The locking lever having the nose 94 is made similar to those usually employed in. the Wahl totalizer to control the register wheel of lowest L to side of a she levers order, said lever being rivet longer lever 96 which is SOT." '32 except that it does not 0 at its free end cooperates like the levers 12 with a screw stop 15 and the universal bar 16. The-construction is such that when the handle I1 is operated the motion of the wheel 82 forces the nose 94 out until the turning of the wheel is nearly completed when said nose is drawn downward by itss'pring 95 into the notch 92 and completes the motion and retains the parts in position.

As thus far described the totalizer mechanism is similar in its construction to that shown in the McCorn Patent No. 1,753,711 referred to above. In addition to the mechanism described above, however, the cross totalizer 38 of the present invention is provided with a set of contact selector gears 91' mounted on a shaft 98, said gears 91 corresponding in number to the number of carrying wheels 63 and constantly meshing therewith. As shown in Fig. 7 which is a view'looking from the left, .these contact selector gears are, or may be, made in three separate planes or strata, the right-hand plane comprising a wheel I having thirty teeth IOI like those of the carrying wheels 63 with which they mesh, and a hub I02. The middle plane is merely a spacing disk I03 of smaller diameter than wheel I00 and used to separate the toothed wheel I00 from a selector disk I04. Spaced at intervals of 120 around the circumference of the selector disk I04 are three selector fingers I05, I05' and I05, generally referred to hereinafter as the selector fingers, I05, which extend beyond the teeth IOI and have right and left-hand sloping cam faces I06 and I01 respectively, (Figs. 3 and 7). The diameter of the selector disk I04 excluding the fingers I05 corresponds to that of the disk I03 and both disks are provided with openings I08 to fit over the hub I02 of the toothed wheel I00. Thus, the three sections I00, I03 and I04 going to make up the contact selector gears 91 may be fastened together by any suitable means such as rivets I09 counter-sunk into the selector disk I04 to form one complete selector gear. It will be understood, however, that if desired these parts may be made integral or formed from one piece of stock.

The selector gears 91 are mounted on the shaft 98 in such manner that when the dial I0 reads zero, the associated selector fingers I05, I05 and I05 will occupy the positions shown in Figs. 1, 2 and 4. As the carrier wheel 63 rotates in a clockwise direction one tooth for each unit of addition, the contact selector gears will rotate in a counter-clockwise direction, the selector fingers I05, I05 and I05 likewise advancing a step for each unit. When the gear has been advanced ten units the finger I05 occupying the upper left or zero position will have moved through ten spaces to the lower or vertical position. It will thus be perceived that each selector finger may occupy within 120 ten different radial positicns 12 apart and corresponding to the ten digits 1 to 0. That is, when the corresponding numeral dial I0 registers zero, the parts will be in the position shown in Fig. 2 as pointed out above; when the dial I0 advances to show 1, the se lector finger I05 will advance 12 to the 1 positic-n; when the dial advances to show 2, the selector finger I05 will advance 12 further to occupy the 2 position and so on. up to the 9" position. Now as the dial is advanced one more unit past the 9 position to bring it back to 0, contact or selector finger I05 will move to the lower vertical position and contact finger I05 will advance into the 0 position previously occupied by finger I05. It will thus be apparent that for any numeral'position of the dial 10 there of the selector fingers at the front of the totalizer will accord with the number present in the totalizer as definitely as the actual numeral dials. As will hereinafter more clearly appear, the

contact selector gears 91, and particularly the selector fingers I05 thereof are used-to aid in closing electric circuits to bring about an actuation of the numeral keys corresponding to their radial positions and hence a printing of the total shown in the cross totalizer 38.

In order to properly punctuate the total between the units and tenths places or at any other points that might be desired, and thus make easier the proper reading of the total, a special selecting device IIO (Figs. 3 and 8) may be provided in the totalizer between the register wheels of the units and tenths orders and also at said other points, if desired. In the present instance this selecting device H0 is shown only in the former place and is used to bring about an actuation of the usual space bar 26 of the typewriting machine, though it might equally well be used in conjunction with other punctuation character keys. Said device H0 is mounted on the shaft 98 along with the contact selector gears 91 and, as shown in Fig. 8, comprises a hubbed disk III, a middle spacing disk II2 like the disk I03, and a selector finger disk II3. All of said disks correspond in diameter to the disk I03, and as in the selector gears 91 the outer two members II2, III are mounted on the hubbed portion of .the disk III, the assembly being secured together by any suitable means such as rivets. The" selector finger disk H3 is provided with one selector finger II 4 which is longer than the fingers I05, but like them it is provided with camming edges H5 and H6. When the device H0 is properly mounted on the shaft 98 the selector finger II4, as shown in Fig. 2, extends in a vertical downward direction, said device IIO being secured against rotationon the shaft 98 by means of a bifurcated arm II! on the disk II3 which embraces the shaft 66 of the idler gears. By being thus held in its vertical downwardly extending position the finger H4 is always in readiness to perform its function of aiding in the closing of an electric circuit which brings about an actuation of space bar 26, as will hereinafter be fully set forth.

' The contact unit The contact unit as shown in Figs. 1, 2, 3 and II and generally designated by the numeral I20, comprises eleven contact-lever supporting-plates I 2I radially arranged 12 apart and held together by left and right end plates I22 and I23 respectively and a curved contact lever guide plate I24, secured to said end plates. Each of the end plates I22 and I23 is bent outwardly to form supporting arms I25 which are secured to brackets I26 and the entire contact unit I 20 is fastened to the cross actuator rods I21 and I28 through said brackets I26. Slotted connections I30 between the supporting arms I25 and the brackets I26 allow the unit I20 to be adjusted laterally with respect to the cross actuator.

Each of the eleven contact-lever supporting 6 plates i2I is provided with ears iBi at the ends thereof which fit into radially aligned slots in the side plates I22 and E23 to support said contact lever plates in their proper positions 12 apart. Since the contact mechanisms supportedon the several plates i2l are all alike, 2. description of one will suffice.

Referring to Fig. 3 it will be observed that a contact lever W2 is pivotally mounted at H33 to the plate HM and secured against rotative move-= ment in a clockwise direction by contact of an arm B34 with a stop pin H35 in the plate ME]. A trip pawl I136 having a slot i371 through which a pin (I38 in the contact lever [I32 extends is allowed a slight sliding movement to the left relative to said contact lever @32 through said pin and slot connection IIB'E, I138. A spring Mil, stretched between depending ears of the pawl [I36 and contact lever iii-i2, has its line of force outside of the pin I138, so that said spring tends to slide said pawl to its right hand position on said pin and also tends to turn the pawl counterclockwise about said pin, pressing its upper edge against a pin M2, projecting from the lever I32. When the pawl E36 is forced-by acontact finger I05 to slide leftward as shown in Fig. 3, a hook MI at its right hand end moves into engagement with the pin H42 and positively prevents clockwise turning of the pawl about the pivot Mt. In this position the pawl I36 and lever i322 are locked together for turning about the pivot H3.

As shown in Fig. 3, the pawl [136 is provided with an arm Mt having a sloping end portion 544 which cooperates with the cam faces i0! and N6 of the selector fingers I105 as the cross totalize'r 38 is moved to the left. From the foregoing it will be apparent that as the cross totalizer 38 is picked up andmoved to the left by the carriage, the above mentioned contact selector fingers will engage with the arms M3 on the contact lever trip pawls i256 according to the several radial positions of said selector fingers, swinging the contact lever I32 from its normal position shown in Fig. 17 to its operated position shown in Fig. 19.

Referring now to Figs. 17, 18 and 19 there are illustrated three positions which the contact lever and trip pawl assume during a single letter space movement of the totalizer to the left. Fig. 3 shows the parts in the Fig. 18 position.

These views also show the relation of the operating parts to the master wheel 30 of the cross actuator during such movement. Immediately before one of the trip pawl arms I43 is about to be engaged by a selector finger 805, the contact lever I32 and its trip pawl are in. normal position as depicted in Fig. 17, said pawl being drawn to the right by its spring I40. Upon a release of the carriage for a letter space movem nt, the

finger I05 engages the arm I43 and moves the pawl to the left to the position shown in Fig. 18. At this point the pawl is in its extreme leftward position with the hook I4I engaging the stud I42, so that further movement of the totalizer to the left will move the contact lever M2 in a counterclockwise direction about its pivot I33. As the finger I05 continues to move to the left with the totalizer in approaching the end of its letter.

space movement, said finger I05 pushes against the arm I43 with a camming action to cause the counter-clockwise movement ofthe contact lever together with its trip pawl. Upon downward movement of these parts the selector finger I05 through its cam face I0I slides onto the inclined edge I44 of the arm H43, 50 that as t carriage and totalizer come to rest the mechanism occupies the position shown in Fig. 19.

Each contact lever is provided with an outwardly extending arm I45 having a rounded end portion I46 which projects through a slot in the plate HM and engages an insulating piece I41 on the left end of an electric contact spring member M8, said contact spring tending to hold the contact lever I32 resiliently in its normal rearward position (Fig. 17). As said contact lever is moved in counter-clockwise direction by the action of the selector finger i025 against the contact trip pawl arm M3, the electric contact spring 8 moves and closes the gap between a contact or circuit closer I50 on the spring M8 and another contact I5I on an outer contact supporting member K49. The contact spring member I548 and the outer contact supporting member I49 are separated at their righthand ends by suitable insulators I52 and secured to the contact lever guide plate M4 by screws i52 A point which is important to the successful operation of the above described mechanism is the location and movement of the contact lever trip pawls 036. When the arms I143 are in the normal Fig. 17 position, that is, when not engaged by the selector fingers I 05, these arms are so located as not to interfere with the movement of the contact selector gear 91 which at the time is geared to the master wheel 36. For example, the dotted showing in Fig. 17 of a selector finger I05 engaging an arm I43 depicts these parts in operative position, that is to say, the contact gear whose dotted finger I05 has depressed the contact lever, is the one whose associated carrier wheel 63 is in mesh with the master wheel and which is about to be rotated to zero. This finger I105 is to the left of and clear or the unengaged arms I43, so that when the selector finger on the engaged pawl is rotated by the master wheel it will not intertere with or be interfered with by the unengaged arms I43. This condition is also shown in Fig. 19. The un engaged pawl arms are always to the right of and entirely clear of the selector finger which will be rotated by the master wheel, and are in position to be picked up at the proper time during the total-printing operation. As pointed out hereinbefore, the whole sensing-unit, including the pawls I36, can be adjusted right and left after loosening the screws I25 (Fig. 11) and the correct positions of the fingers I43 to give the best results can thus be arrived at.

Having thus described the mechanism for closing thegap between the contacts I50 and lil and thus closing the circuits in which said contacts are included after the machine is otherwise conditioned, I shall now describe the electrical connections and mechanisms which effect an actuation of a numeral key or a tripping of the space bar each time such a contact is made in the printing of a total.

As explained above, and as shown in Fig. 2, there are eleven supporting plates I2I in the contact unit I20 and all of these plates carry contacting mechanism like that shown in Figs. 3, 1'7, 18

' ginning at the top of the contact unit I20 the first ten contact-lever supporting plates I2I correspond to the numerals 0 to 9 and allare arranged 12 apart on an arc of a circle, and each is actuated by a selecting finger I05, I06 or I05 which happens to be set in radial cooperative relation therewith. The eleventh contact lever plate, however, is for the space key and is offset outwardly from the arc of the ten numeral contact plates an amount equal to-the diiference in length between the selector fingers I05 and the finger I I4. Hence the contacting mechanism for the space key will never be actuated by the fingers I05 even though they are radially in line with it, butsaid mechanism will be operated in exactly the same manner as described above only by the finger II4.

Referring now to the wiring diagram of Fig. 16, it will be observed that the contact I50 of each of the contacting mechanisms for the numerals to 9 is connected by a wire or conductor I53 to a solenoid I54 having a plunger or core I55, the solenoid then being connected to a source of power through a conductor I56. Likewise, the contact I50 for the space key is connected by a conductor I53 to a solenoid I54 having a plunger or core I 55, said solenoid being of greater strength than the solenoids I54. The contacts II are all connected to a common conductor which leads to a switch or contact I51 for the total key to be hereinafter described, then to a rheostat I58 and on to the source of power, said rheostat being adjusted once for any given source of power. Thus each of the numeral contact switches and the space key switch comprising the contacts I50 and I5I closes a circuit to energize a solenoid, said circuit being interrupted by the total key switch I51 so that no solenoid can be energized unless said total key switch is closed. All of the above mentioned switches, including the total switch I51, may be shunted by a condenser I60, to decrease the arcing as the circuits are opened.

Each of the solenoids I54 for the numeral keys 0 to 9 is mounted with its plunger I55 extending horizontally forward, on a crossbar I6I secured to one of the regular frame members I62 underneath the machine (Fig. 1) by any suitable means such as screws I 63. The position of each of these solenoids I54 is such that a link I64, pivotally and detachably secured to the plunger I55, as at I65, may be pivotally connected to an extension I66 on the usual cam latch trip lever I 61. In this manner the solenoid plungers for the keys 0" to 9 are attached to the cam latch trip levers of the corresponding numeral keys, so that if a selector finger I05, I05 or I05 of one of the contact selector gears 81 is set in the 8 position, for example, and the cross totalizer moves to the left to bring about a closing of the contacts I50, I5I for this position, assuming that the total switch I51 is closed, the solenoid for the 8 key will be energized. Energization of the solenoid will cause its plunger to be drawn in, thus drawing the link I64 rearwardly to bring about a tripping of the cam latch or trip pawl I61 for the 8 key. As is well known this tripping of the cam latch I61 will effect a computation, either adding or subtracting, of the amount, (eight in the present instance) and a printing of the corresponding numeral.

Referring to Fig; 1 is will be seen that the solenoid I 54 for the space key 26 may be secured in a vertical position by a bracket I68 to the base frame section 20 at either side thereof in a position directly below the usual rearwardly extending key lever I of said space, key. .A link I1I pivotally attached to the plunger I55 and the lever I10 establishes a connection between these two members, so that when the solenoid is energized the plunger and link I1I will be drawn downwardly to effect an actuation of the space bar and a consequent letter spacing of the carriage. If other methods than the above were used to space the carriage the solenoid I54 could easily be arranged to bring about an actuation of the proper mechanism.

In the event that it is deemed advisable or desirable to effect an automatic punctuation in all of the columns where entries are made, instead of in the total column alone, it is merely necessary to run the conductor leading from the contact I5I for the space bar directly to the source of power instead of having it lead to the total switch as shown in Fig. 16. Thus each time the gap between the contacts I50(and I 5I for the space bar was closed, the associated solenoid I54 would be energized to effect an actuation of the space bar and such actuation would not depend on the closing of the total switch I51.

The total key an arm which extends forward horizontally and carries a total key I14 on the end thereof (Fig. 1). The other arm of the bell crank lever I13 extends downwardlyand is connected by means of a link I to the lower arm of a second bell crank lever I16-which is pivoted by means of a screw I11 to a bracket I18 attached to the front upright frame member. As shown in Figs. 1 and 6, a lug I80 provided on the upper arm of the bell crank lever I16 is adapted to be engaged by a cam latch I8I, said cam latch being formed on one end of a lever I82 which is pivoted at I83 to a) bracket I84 on the right front corner post on the upper frame. The construction is such that when the total key I14 is depressed, the link I15 moves upwardly and rearwardly turning the bell crank I16 in a counter-clockwise direction as the parts are shown in Fig. 1 therebycausing the lug I80 to move forward and be caught behind the cam latch I8I, thus holding the total key in its depressed position.

As the link I15 moves upwardly and rearwardly when the total key is depressed, a lug I85 provided on said link engages an insulating pece on a spring contact member I86 of the total switch I51 and causes a closing of the contacts of said switch. The total switch is also mounted on the side of the upper frame section 2I by meansof a bracket I81 and insulated therefrom by any suitable insulators, such as the fiber pieces I88. The total key is limited in its upward movement by contact of the downwardly extending arm of the bell crank lever I13 with a lug I90, and is resiliently held in its upper position by a spring I9I which extends between a lug ISII on v the frame 2I and the link I15. It will thus be I seen that as the total key'is depressed it causes a closing of the total switch I 51 which remains closed by reason of the engagement of the lug I80 with the cam latch I8I.

In order to release the total key from its locked position at the proper time, use is made of some of the actuating parts of the well known cross totalizer interlock mechanism present in computing mechanism of the Wahl type, and which prevents the operation of the computing mechanism when the cross truck is in normal position as is Well known. Referring to Figs. 3, 6 and 11 it will be seen that the normal position of the cross truck 40 is determined by the contact of an abutment I92 on said truck, with a lever I93 pivoted in the frame work of the cross actuator at I94 and adapted to have its upper end contact withsaid abutment I92. A slidable member I95 serves to transmit the motion of the lever I93 to another lever I95 and thence to the mechanism (not shown), said lever I93 being given a tendency to turn in a counter-clockwise direction by a spring I 9? extending between the slidable member I55 and the left-hand cross actuator frame plate 6M1.

When the cross truck it] has been picked up by the pick-up lug of one of the vertical tctalizers as the carriage moves to the left carrying the totalizer through a computing zone, the lever I93 moves away from the frame plate 45 under the urge of spring I9'I to the position shown in Fig. 3. The left end of the lever I82 is provided with a lug I98 (Fig. 6) which fits into a slot I99 in the sliding member I95 so that when the cross truck is released and the abutment I92 strikes the lever M13 moving it and the sliding member I95 to the right, the lever I82 will be turned in a counter-clockwise direction. Such'movement of the lever I32 will release the lug I from its engagement with the cam latch IIiI, allowing the total key to spring back to normal position under the urge of the spring I9! and thus open the total switch I51.

From the foregoing it will be apparent that when the total key I'M is depressed preparatory to the printing of a total, said key will close the gap between the contacts of the total switch I5I, keeping said switch closed until the total is printed and the cross truck 40 springs back to normal position. Therefore, as each of the selector fingers I05 or the finger IM engages a trip pawl arm I43 to bring about a closing of the gap between thecontacts I50 and I5I, there will be a completed circuit to the source of power to bring about an energization of the associated solenoid I54 or the solenoid I56 and a consequent computation and printing of the corresponding numeral or tripping of the space key.

The operation of the machine for, debit halcmces I have described in detail the mechanism necessary to carry out my invention for the automatic printing of an ordinary positive total or debit balance. I shall now describe the operation of the same, taking as an example a definite number in the totalizer and following the operation of the machine step-by-step during the automatic printing of such a number.

For the purposes of this description it will be assumed that the vertical totalizers 3|, 3H and 3| have passed through the computing zone and that the amounts of the previous balance, charges and credits have been introduced into the respective vertical totalizers and further, that the cross totalizer 38 has been carried across its master wheel three times so that these amounts have all been entered into said cross totalizer. As hereinbefore explained, the amount now showing in the cross totalizer will be the new balance or total which is to be printed and is the result of adding the charges to the previous balance and subtracting the credits therefrom. Assuming that the result of these computations is, for example 32.47 which amount shows on the dials of the cross totalizer, the selector fingers I05 associated with the carrying wheels of the dials for each digit of this total will occupy corresponding radial positions. That is, one of the selector fingers I05 for the tens place will be set at the 3position so as to be radially in line with the contact lever and trip pawl which control the closing of the circuit for the solenoid which actuates the 3 key lever. Likewise a selector finger for the units place will be set in the 2 position, a tenthsplace selector finger in the 4. position and a hundredths place selector finger in the 7 position. It is further assumed that the cross totalizer has been released from the vertical totalizer 3| for the credit column and is back in normal position. In other words, everything is in readiness for printing the total automatically digit by digit and at a common printing point.

Now, in order to bring about the automatic printing of the total, the operator glances at the cross totalizer to see the amount that is to be printed. At this observation it is only necessary to note what decimal place the first digit of the total occupies, and in the present instance this is the tens place. The operator then presses the tabulator key corresponding to this decimal place and the typewriter carriage advances to the proper point. As the carriage advances moving the last vertical totalizer 3I into the computing zone by the tabulation, the pick-up lug 41 of this last vertical totalizer 3| engages the hook $8 on the pick-up beam 50 and the cross truck II] is given a corresponding movement to the left, so that when the carriage comes to rest, the carrier wheels for the tens place of both the vertical and cross totalizers are over their respective master wheels. When the cross totalizer 38 is approaching this position the contact pawl arm I43 on the contact plate which is radially in line with the "3 position, is engaged and moved to the position shown in Fig. 19 in a manner hereinbefore described. Thus, when the cross totalizer comes to rest at the tens position the gap between the contacts I50 and |5I of the contact mechanism for the 3 position is closed and the carrier gear 63 for the register wheels in the tens place is overthe master wheel.

All that remains now for the operator to do is to depress the total key I14 whenthe carriage comes to rest after the tabulating operation. As explained above the depression of the total key I'M closes the total switch I51, and since the cross truck 40 is not in normal position the lug I80 will be engaged by the cam latch I8l to hold the total key in its depressed position and hence keep the total switch closed. With the total switch I5'I closed and the contact switch for the 3 position of the selector finger closed, the solenoid I54 which controls the actuating mechanism for the 3 key lever will be in a closed circuit with the source of power and will become energized. Energization of this solenoid I54 will draw its associated plunger I55 rearwardly to cause a counter-clockwise movement of the cam latch trip pawl I67. Such movement of the trip pawl for the 3 key lever brings about atripping of the associated cam latch I61 The action which follows the tripping of any cam latch is fully set forth in the above mentioned application of Hart, Serial No. 510,941, and will be described more fully hereinnafter. Suffice it to say for the present that it causes an addition of 3 into the vertical totalizer in the tens place, a subtraction of 3 in the cross-totalizer in the tens place since the vertical totalizer 3| is provided with a subtracting cam, and an actuation of the 3 type bar which prints this digit on the bill and record sheet and causes the carriage to move one space to the left through the operation of the heel of the actuated type bar on the universal bar which controls the escapement mechanism.

Upon this next step movement of the carriage which moves both totalizers so that their carrying wheels in the units place are over their respective master wheels, the selector finger of the units contact selector gear which is set for the 2 position moves the trip pawl arm I 43 in radial alignment therewith to close the contact switch for the numeral 2. Since the total switch is still closed, energization of the solenoid for the "2" key lever will follow immediately and 2 will be added in the vertical totalizer in the units place, subtracted in the cross totalizer in the units place, the numeral 2 will be printed on the bill and record sheet and the carriage will again move one space to the left. Both totalizers,

' with this space to the left, are moving into the decimal point position and a space in the printing of a fractional number is used to indicate this point.

As the cross totalizer moves into the decimal point position the selector finger H4 which extends vertically downward engages the trip pawl arm Hl3 radially in line with it which controls the space key through the solenoid I54. When the carriage comes to rest the contact mechanism occupies the Fig. 19 position and the circuit for the solenoid I54 is closed. Energization of this solenoid causes a downward movement of the plunger I55 and a consequent downward movement of the space bar lever I10 which effects a letter space movement of the carriage and cross truck to the left in the usual manner.

In a manner similar to that explained above for the tens and units digits of the total, the tenths and hundredths digits are subsequently added into the active vertical totalizer, subtracted out of the cross totalizer and printed on the bill and record sheets one at a time. As the carriage moves a space to the left after printing the 7 or last digit of the total, the cross truck is released from the engaged vertical totalizer in a manner explained above, and it springs back to normal position. This causes the release of the lug I80 from the cam' latch, a return of the total key to normal position, and a consequent opening of the total switch I51. Thus, the vertical totalizer for the balance column shows the new balance or the accumulative balance, the cross totalinn is cleared, and everything is in readiness for 1 another line of computation and an automatic printing of the total which will take place in exactly the same manner. From the foregoing it will be apparent .that .once the carriage is set in proper denominational position and the total key is depressed, the total is printed automatically.

If, however, at any time the amount of credit entered into the cross totalizer is greater than the sum of the previous balance and the charge, the balance will become a credit balance rather than a debit balance. In algebraic totalizers a credit balance is regarded as a negative balance and is evidenced by a 9 appearing in the highest decimal order of the totalizer instead of a This is due to the fact that when the credit was entered into the cross totalizer the register wheels were rotating in a subtracting direction, and when going past 0 in this direction the 9 will appear. As in the present totalizer 38, which has only one set of dials, the amount shown on the dials when the balance is negative will be what is sometimes called the arithmetical complement of the credit balance. However, in this, as in most algebraic machines, the true credit balance is printed, not from this arithmetrical complement but from the so-called nines comple ment which can be obtained by subtracting the fugitive 1 from the arithmetical complement; and means for this purpose Will presently be described.

It will be apparent that when it is necessary to print a credit balance, and especially to do so automatically, certain additions and changes will have to be made in the ordinary debit balance mechanism in order that it may be done properly. When printing an ordinary debit balance, as explained above, the vertical master wheel is set for add to add the amount to the accumulative total and the cross master wheel is set for subtract to clear the cross totalizer. If now a credit balance or negative total is to be printed the vertical master wheel must be changed to subtract to deduct from the accumulative total, and the cross master wheel changed to add since the amount printed is the complement of the amount shown in the cross totalizer.

Referring to Fig. 12 it will be observed that in the main the ordinary gear shift mechanism shown and described in the Wahl Patent No. 1,270,471 is used in the present construction to accomplish this change of the master wheels. Such mechanism, as is well known, comprises a manually operable shift lever (not shown) which is pivoted at 200 to an arm 20| which controls the movement of a floating lever 202 through a bell crank lever 203 and a connecting link 204. Said floating lever 202 in turn controls the position of actuating or change gears 205 for the master wheel 34 for the vertical totalizers. When the manually operable shift lever is in' its uppermost position the master wheel 34 will rotate in adding direction and the parts occupy the relationship shown in Fig. 12, the construction being such that when the arm is moved downward to its lower position the gears 205 will be shifted and the master wheel will rotate in a subtracting direction. With the shift lever in an intermediate or disconnect position the master wheel will not rotate at all.

In alike manner the cross master wheel 36 is controlled by a cam follower 206 which is mounted at the front of the vertical actuator in position to be engaged by the cams 206 (Fig. 2) on the vertical totalizers. The follower 206 controls the shifting of cross actuating or change gears 20'! through a well known train of connections including lever 208, link 2l0, floating lever 2, link 2|2, and a lever 2l3 pivoted at 214 to an actuator frame member. As shown in Fig. 12 the gears 20! are in adding relation but said gears may be shifted like the gears 205 to sub-' tract and disconnect positions by movement of the cam follower 206.

A correction key is used in this type of gear shiftmechanism which when depressed reverses the action of both master wheels whether set for addition or subtraction. In case either master Wheel is set for non-add or disconnect that setting will be retained if the correction key is depressed. This key is in the nature of a lever of the first order pivoted at H and connected by a link 2I6 to a bell crank 2H, the upstanding arm of which is pivoted to a rod 2l8, said rod being pivoted to both floating levers 202 and 2| l. he construction is such that a depression of the. 

